// Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. #ifndef SRC_BASE_OBJECT_H_ #define SRC_BASE_OBJECT_H_ #if defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS #include // std::remove_reference #include "base_object_types.h" #include "memory_tracker.h" #include "v8.h" namespace node { class Environment; class IsolateData; class Realm; template class BaseObjectPtrImpl; namespace worker { class TransferData; } extern uint16_t kNodeEmbedderId; class BaseObject : public MemoryRetainer { public: enum InternalFields { kEmbedderType, kSlot, kInternalFieldCount }; // Associates this object with `object`. It uses the 1st internal field for // that, and in particular aborts if there is no such field. // This is the designated constructor. BaseObject(Realm* realm, v8::Local object); // Convenient constructor for constructing BaseObject in the principal realm. inline BaseObject(Environment* env, v8::Local object); ~BaseObject() override; BaseObject() = delete; // Returns the wrapped object. Returns an empty handle when // persistent.IsEmpty() is true. inline v8::Local object() const; // Same as the above, except it additionally verifies that this object // is associated with the passed Isolate in debug mode. inline v8::Local object(v8::Isolate* isolate) const; inline v8::Global& persistent(); inline Environment* env() const; inline Realm* realm() const; // Get a BaseObject* pointer, or subclass pointer, for the JS object that // was also passed to the `BaseObject()` constructor initially. // This may return `nullptr` if the C++ object has not been constructed yet, // e.g. when the JS object used `MakeLazilyInitializedJSTemplate`. static inline void SetInternalFields(v8::Local object, void* slot); static inline void TagNodeObject(v8::Local object); static void LazilyInitializedJSTemplateConstructor( const v8::FunctionCallbackInfo& args); static inline BaseObject* FromJSObject(v8::Local object); template static inline T* FromJSObject(v8::Local object); // Make the `v8::Global` a weak reference and, `delete` this object once // the JS object has been garbage collected and there are no (strong) // BaseObjectPtr references to it. void MakeWeak(); // Undo `MakeWeak()`, i.e. turn this into a strong reference that is a GC // root and will not be touched by the garbage collector. inline void ClearWeak(); // Reports whether this BaseObject is using a weak reference or detached, // i.e. whether is can be deleted by GC once no strong BaseObjectPtrs refer // to it anymore. inline bool IsWeakOrDetached() const; inline v8::EmbedderGraph::Node::Detachedness GetDetachedness() const override; // Utility to create a FunctionTemplate with one internal field (used for // the `BaseObject*` pointer) and a constructor that initializes that field // to `nullptr`. static v8::Local MakeLazilyInitializedJSTemplate( IsolateData* isolate); static v8::Local MakeLazilyInitializedJSTemplate( Environment* env); // Setter/Getter pair for internal fields that can be passed to SetAccessor. template static void InternalFieldGet(v8::Local property, const v8::PropertyCallbackInfo& info); template static void InternalFieldSet(v8::Local property, v8::Local value, const v8::PropertyCallbackInfo& info); // This is a bit of a hack. See the override in async_wrap.cc for details. virtual bool IsDoneInitializing() const; // Can be used to avoid this object keeping itself alive as a GC root // indefinitely, for example when this object is owned and deleted by another // BaseObject once that is torn down. This can only be called when there is // a BaseObjectPtr to this object. inline void Detach(); static inline v8::Local GetConstructorTemplate( Environment* env); static v8::Local GetConstructorTemplate( IsolateData* isolate_data); // Interface for transferring BaseObject instances using the .postMessage() // method of MessagePorts (and, by extension, Workers). // GetTransferMode() returns a transfer mode that indicates how to deal with // the current object: // - kUntransferable: // No transfer is possible, either because this type of BaseObject does // not know how to be transferred, or because it is not in a state in // which it is possible to do so (e.g. because it has already been // transferred). // - kTransferable: // This object can be transferred in a destructive fashion, i.e. will be // rendered unusable on the sending side of the channel in the process // of being transferred. (In C++ this would be referred to as movable but // not copyable.) Objects of this type need to be listed in the // `transferList` argument of the relevant postMessage() call in order to // make sure that they are not accidentally destroyed on the sending side. // TransferForMessaging() will be called to get a representation of the // object that is used for subsequent deserialization. // The NestedTransferables() method can be used to transfer other objects // along with this one, if a situation requires it. // - kCloneable: // This object can be cloned without being modified. // CloneForMessaging() will be called to get a representation of the // object that is used for subsequent deserialization, unless the // object is listed in transferList, in which case TransferForMessaging() // is attempted first. // After a successful clone, FinalizeTransferRead() is called on the receiving // end, and can read deserialize JS data possibly serialized by a previous // FinalizeTransferWrite() call. enum class TransferMode { kUntransferable, kTransferable, kCloneable }; virtual TransferMode GetTransferMode() const; virtual std::unique_ptr TransferForMessaging(); virtual std::unique_ptr CloneForMessaging() const; virtual v8::Maybe>> NestedTransferables() const; virtual v8::Maybe FinalizeTransferRead( v8::Local context, v8::ValueDeserializer* deserializer); // Indicates whether this object is expected to use a strong reference during // a clean process exit (due to an empty event loop). virtual bool IsNotIndicativeOfMemoryLeakAtExit() const; virtual inline void OnGCCollect(); virtual inline bool is_snapshotable() const { return false; } private: v8::Local WrappedObject() const override; bool IsRootNode() const override; static void DeleteMe(void* data); // persistent_handle_ needs to be at a fixed offset from the start of the // class because it is used by src/node_postmortem_metadata.cc to calculate // offsets and generate debug symbols for BaseObject, which assumes that the // position of members in memory are predictable. For more information please // refer to `doc/contributing/node-postmortem-support.md` friend int GenDebugSymbols(); friend class CleanupQueue; template friend class BaseObjectPtrImpl; v8::Global persistent_handle_; // Metadata that is associated with this BaseObject if there are BaseObjectPtr // or BaseObjectWeakPtr references to it. // This object is deleted when the BaseObject itself is destroyed, and there // are no weak references to it. struct PointerData { // Number of BaseObjectPtr instances that refer to this object. If this // is non-zero, the BaseObject is always a GC root and will not be destroyed // during cleanup until the count drops to zero again. unsigned int strong_ptr_count = 0; // Number of BaseObjectWeakPtr instances that refer to this object. unsigned int weak_ptr_count = 0; // Indicates whether MakeWeak() has been called. bool wants_weak_jsobj = false; // Indicates whether Detach() has been called. If that is the case, this // object will be destroyed once the strong pointer count drops to zero. bool is_detached = false; // Reference to the original BaseObject. This is used by weak pointers. BaseObject* self = nullptr; }; inline bool has_pointer_data() const; // This creates a PointerData struct if none was associated with this // BaseObject before. PointerData* pointer_data(); // Functions that adjust the strong pointer count. void decrease_refcount(); void increase_refcount(); Realm* realm_; PointerData* pointer_data_ = nullptr; }; // Global alias for FromJSObject() to avoid churn. template inline T* Unwrap(v8::Local obj) { return BaseObject::FromJSObject(obj); } #define ASSIGN_OR_RETURN_UNWRAP(ptr, obj, ...) \ do { \ *ptr = static_cast::type>( \ BaseObject::FromJSObject(obj)); \ if (*ptr == nullptr) return __VA_ARGS__; \ } while (0) // Implementation of a generic strong or weak pointer to a BaseObject. // If strong, this will keep the target BaseObject alive regardless of other // circumstances such as the GC or Environment cleanup. // If weak, destruction behaviour is not affected, but the pointer will be // reset to nullptr once the BaseObject is destroyed. // The API matches std::shared_ptr closely. However, this class is not thread // safe, that is, we can't have different BaseObjectPtrImpl instances in // different threads referring to the same BaseObject instance. template class BaseObjectPtrImpl final { public: inline BaseObjectPtrImpl(); inline ~BaseObjectPtrImpl(); inline explicit BaseObjectPtrImpl(T* target); // Copy and move constructors. Note that the templated version is not a copy // or move constructor in the C++ sense of the word, so an identical // untemplated version is provided. template inline BaseObjectPtrImpl(const BaseObjectPtrImpl& other); inline BaseObjectPtrImpl(const BaseObjectPtrImpl& other); template inline BaseObjectPtrImpl& operator=(const BaseObjectPtrImpl& other); inline BaseObjectPtrImpl& operator=(const BaseObjectPtrImpl& other); inline BaseObjectPtrImpl(BaseObjectPtrImpl&& other); inline BaseObjectPtrImpl& operator=(BaseObjectPtrImpl&& other); inline void reset(T* ptr = nullptr); inline T* get() const; inline T& operator*() const; inline T* operator->() const; inline operator bool() const; template inline bool operator ==(const BaseObjectPtrImpl& other) const; template inline bool operator !=(const BaseObjectPtrImpl& other) const; private: union { BaseObject* target; // Used for strong pointers. BaseObject::PointerData* pointer_data; // Used for weak pointers. } data_; inline BaseObject* get_base_object() const; inline BaseObject::PointerData* pointer_data() const; }; template using BaseObjectPtr = BaseObjectPtrImpl; template using BaseObjectWeakPtr = BaseObjectPtrImpl; // Create a BaseObject instance and return a pointer to it. // This variant leaves the object as a GC root by default. template inline BaseObjectPtr MakeBaseObject(Args&&... args); // Create a BaseObject instance and return a pointer to it. // This variant detaches the object by default, meaning that the caller fully // owns it, and once the last BaseObjectPtr to it is destroyed, the object // itself is also destroyed. template inline BaseObjectPtr MakeDetachedBaseObject(Args&&... args); } // namespace node #endif // defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS #endif // SRC_BASE_OBJECT_H_